Projektinformation
Beskrivning
Gut beneficial bacteria produce a newly discovered molecular syringe, so called Bacteroides
injection system (BIS) and genes thereof were shown to be predominant in 99% of healthy human
beings. Structure and function of these injection systems within the gut microbiome is to date
unknown. The proposed project will solve the BIS structure in various functional states using cryo-electron microscopy (cryo-EM), supported by de novo structure prediction
(AlphaFold2). We reveal the syringes’ molecular design and mechanistic function in native and nonnative
environment. Furthermore, we will reveal the BIS target receptor using receptor
binding assays, surface plasmon resonance (SPR), mass spectrometry and microscopy revealing
eukaryotic or bacterial cells as a target. CRISPR gene edited Bacteroides strains
will be made to investigate the syringes’ importance in bacterial competition and potential to fight
pathogens using in vitro and in vivo bacterial and mouse model systems, respectively. BIS will be
re-designed for treatment of infections and resistance by modifying cargo and fiber
legs using modelling and in vitro and in vivo transport and efficacy assays. The proposed research
package will present the first BIS structure, the effect and importance on gut microbiota and show its
potential as targeted drug delivery tool and for microbiome editing to fight antimicrobial resistance.
injection system (BIS) and genes thereof were shown to be predominant in 99% of healthy human
beings. Structure and function of these injection systems within the gut microbiome is to date
unknown. The proposed project will solve the BIS structure in various functional states using cryo-electron microscopy (cryo-EM), supported by de novo structure prediction
(AlphaFold2). We reveal the syringes’ molecular design and mechanistic function in native and nonnative
environment. Furthermore, we will reveal the BIS target receptor using receptor
binding assays, surface plasmon resonance (SPR), mass spectrometry and microscopy revealing
eukaryotic or bacterial cells as a target. CRISPR gene edited Bacteroides strains
will be made to investigate the syringes’ importance in bacterial competition and potential to fight
pathogens using in vitro and in vivo bacterial and mouse model systems, respectively. BIS will be
re-designed for treatment of infections and resistance by modifying cargo and fiber
legs using modelling and in vitro and in vivo transport and efficacy assays. The proposed research
package will present the first BIS structure, the effect and importance on gut microbiota and show its
potential as targeted drug delivery tool and for microbiome editing to fight antimicrobial resistance.
Status | Pågående |
---|---|
Gällande start-/slutdatum | 2024/01/01 → 2027/12/31 |
Samarbetspartner
- Lunds universitet (huvudsaklig)
Finansiering
- Swedish Research Council